Talk:Gleason's theorem/GA1

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Reviewer: Jakob.scholbach (talk · contribs) 20:18, 6 January 2020 (UTC)Reply

Thanks, XOR'easter for the nomination -- I will be doing a review as soon as I can; other reviewers are welcome! Jakob.scholbach (talk) 20:18, 6 January 2020 (UTC)Reply

I'm an expert on the subject. I'll add some comments here in the hope that they will be useful. If you so wish I can also provide a more in-depth review. First of all, the article claims that Gleason's theorem rules out local hidden variables. This is not true. It rules out noncontextual hidden variables. See for example Kochen–Specker theorem for a proper take on the relationship between nonlocality and contextuality. What is taken to rule out local hidden-variables is Bell's theorem, first because it deals directly with locality, and secondly because its assumptions are much weaker. The fact that Gleason's assumptions are widely considered to be too strong should be stated in the article. Also, it should be explained why Gleason's assumptions are better than von Neumann's (it is because von Neumann assumed linearity of expectation values for non-commuting observables, which is an unmotivated assumption of a technical flavour, whereas Gleason assumed non-contextuality, which is both well-motivated and physically meaningful).

Also, I find the article unnecessarily heavy in jargon. Why use "frame function", instead of simply "probability function"? Why use "bivalent probability measures", instead of simply "deterministic probability measure"?

Furthermore, the "Implications" section contains some dubious claims. It says, for example, that "Alternatively, such approaches as relational quantum mechanics and some versions of quantum Bayesianism employ Gleason's theorem as an essential step in deriving the quantum formalism from information-theoretic postulates." This is not true, and not supported by the cited references Barnum et al. (2000) and Wilce (2017) (I couldn't access Cassinelli and Lahti (2017)). Also the claim "Because Gleason's theorem yields the set of all quantum states, pure and mixed, it can be taken as an argument that pure and mixed states should be treated on the same conceptual footing, rather than viewing pure states as more fundamental conceptions" is strange. Gleason's theorem has hardly anything to do with this discussion, and the reference cited to support this merely notes that "Gleason’s theorem might be interpreted as telling us exactly why it is the most general such state". Tercer (talk) 12:01, 11 January 2020 (UTC)Reply

Thanks for your comments. The point about noncontextual hidden variables is a good one — the body of the article goes into detail on this, but perhaps the qualification should be worked into the introduction as well. "Frame function" can probably be replaced with "probability measure" here and there, though we should I think mention the terminology since it was Gleason's and is still used in various places. "Bivalent probability measure" was, I think, the jargon in the article before I came along, and probably copied over from whatever source was originally used c. 2006. It can probably be changed to something more illuminating. The bit about "some versions of Quantum Bayesianism" is true — Bub and Pitowsky make much of it [1][2][3], as did Carl Caves and coauthors back in the day [4]. The "relational quantum mechanics" part is supportable in principle [5], but I wouldn't mind taking it out. Wilce (2017) does talk about Gleason and reconstruction: From the single premise that the “experimental propositions” associated with a physical system are encoded by projections in the way indicated above, one can reconstruct the rest of the formal apparatus of quantum mechanics. The first step, of course, is Gleason's theorem, which tells us that probability measures on ${\displaystyle L(H)}$  correspond to density operators. [...] The point to bear in mind is that, once the quantum-logical skeleton ${\displaystyle L(H)}$  is in place, the remaining statistical and dynamical apparatus of quantum mechanics is essentially fixed. In this sense, then, quantum mechanics—or, at any rate, its mathematical framework—reduces to quantum logic and its attendant probability theory. Cassinelli and Lahti (2017) is explicitly about reconstructing quantum theory by way of Solèr and Gleason. I think there's a problem of labels — e.g., where's the line between quantum information and quantum logic? — so I'll try revising that passage of the article.

Looking at that passage in Wallace's chapter, I think it's more about what he calls "inferential conceptions" of physical theories ("on the inferential conception there is even less reason to deny that a mixed state is a legitimate state of a system", etc.). Since he only touches on Gleason's theorem parenthetically, I think it's better to take that line out rather than rewrite it. XOR'easter (talk) 18:57, 11 January 2020 (UTC)Reply

I've removed "bivalent", defined "frame function" and made assorted other modifications. XOR'easter (talk) 22:23, 11 January 2020 (UTC)Reply

I think it is fine to use the name "frame function", but you should define where it first appears. Currently the article introduces them without using the name, and afterwards introduces them again and gives the name. The reader doesn't know that they are the same thing, especially because in the first case the article emphasises that they are non-contextual, and in the second case it doesn't mention it (the fact that Gleason allowed the weight to be different than one is a mathematical detail of no consequence, since you can always renormalize such frame function to have weight 1. I wouldn't even mention that on the article.). Tercer (talk) 13:39, 12 January 2020 (UTC)Reply

Fair points. In that paragraph, I was trying to stick with Gleason's terminology, as part of summarizing his original argument. I still think that's a reasonable thing to do at that point in the article, but I will try to tie it better with the previous section. XOR'easter (talk) 22:10, 12 January 2020 (UTC)Reply

I'm not sure historical accuracy is such a good idea, as the primary source is often rather obscure. But if you want to describe what Gleason said, I think you can use the same definition of frame function in both parts and add a remark in Gleason's part to the effect that he actually allowed the function to sum to any non-negative real number, but that one can assume wlog that it sums to 1. Tercer (talk) 22:35, 12 January 2020 (UTC)Reply

That's much like what I was considering doing. I'll go off and try to find a decent phrasing now. XOR'easter (talk) 22:37, 12 January 2020 (UTC)Reply

Great, I think the result was quite decent. Tercer (talk) 23:18, 12 January 2020 (UTC)Reply

I'm glad you appreciated my comments. I don't think it makes sense to call Bub and Pitowsky quantum Bayesians. They support a Bayesian (subjectivist) approach to quantum logic, which confusingly enough is not the same as Fuchs' quantum Bayesianism. Furthermore, Pitowsky died in 2010, the year when quantum Bayesianism was named and defined. Ironically enough, the paper you cite from Bub explains the difference between his and Fuchs' approach. Now, the quantum logic people indeed use Gleason's theorem as a foundational result, which is probably what you should mention in the article.

It's true that in this 2001 paper you link by Caves, Fuchs, and Schack (who are QBists without any doubt), they do use Gleason's theorem to get Born's rule, but that's not the approach they favour anymore. After they invented SIC-POVMs they decided to use them to postulate the Born rule as fundamental. This is the approach used in this 2010 paper, the one that named and defined quantum Bayesianism, does not even mention Gleason's theorem.

The reconstructions you mention by Wilce, Cassinelli, and Lathi are explicitly quantum logic reconstructions, that indeed do use Gleason's theorem.

Trassinelli's reference is a weird one. He is advocating a marriage between quantum logic and RQM. Which is fine, but it is not how RQM is usually understood, and Gleason's theorem again plays its role in the quantum logic part of the argument. Tercer (talk) 15:00, 12 January 2020 (UTC)Reply

I've always heard "quantum Bayesianism" defined more broadly than "QBism"; the former includes Bub and Pitowsky, while the latter is what Fuchs, Mermin and Schack advocate. See for example Duwell (2010). To avoid the ambiguity, I've rewritten that passage. XOR'easter (talk) 15:44, 12 January 2020 (UTC)Reply

Ah, so that's what you had in mind! In my head they were synonyms, but I'm glad you agree that they are easy to confuse. Tercer (talk) 17:00, 12 January 2020 (UTC)Reply

Yes, the "some varieties of quantum Bayesianism" phrasing made sense in my brain, but that's no guarantee it would make sense anywhere else! :-) I got curious and dug through the history for where the "relational quantum mechanics" part came in. Turns out that it was added in September 2006. I probably should have cut it out or changed it to talk about quantum logic instead, but it slipped through the net. XOR'easter (talk) 22:10, 12 January 2020 (UTC)Reply

Review by Jakob.scholbach (talk)

First off: I am by no means an expert on this topic; I am a mathematician who knows what a Hilbert space and a probability measure is, but otherwise the topics in this article are new to me. This will also no doubt be reflected in my comments below.

Overview

• A general question: is it correct that Gleason's theorem is a theorem which can be stated completely in terms of mathematical notions such as, say, Hilbert space etc. and that (quantum) physics uses an interpretation of these mathematical notions? If so (which I suspect), it might be worthwhile separating a bit more the mathematical basis of the story and the physical interpretation.
• Per WP:MOS (MOS:WE) I think it is advisable not to address the reader directly. This happens in many spots, e.g. "Consider a quantum system..."
• "given that each quantum system is associated with a Hilbert space" -- the ignorant reader (like me) had to guess (?) that a quantum system is just a physics-lingo for a Hilbert space. Is that correct? If yes, such a statement belongs further up in the section, I think.   Done Moved during reorganization XOR'easter (talk) 17:24, 23 January 2020 (UTC)Reply
• "particular mathematical entities" -- do you mean probability measures here? The vagueness of the phrasing does not seem to help (me) here.   Done Rewritten to be more precise XOR'easter (talk) 17:24, 23 January 2020 (UTC)Reply
• I don't see the point in the assertion that the structure of a quantum state space (again ?? = Hilbert space) follows from Gleason's theorem.
• "For simplicity, we can assume" -- maybe rephrase as "For the purposes of this overview, the Hilbert space is assumed to be finite-dimensional in the sequel." ? Also, it would seem to make sense how this assumption is a simplification?   Done XOR'easter (talk) 17:24, 23 January 2020 (UTC)Reply
• "Equivalently, we can say that ..." -- is that really equivalent? After all you need to choose a basis to begin with, no? Also "we can say that" is redundant.   Done Passage revised XOR'easter (talk) 17:24, 23 January 2020 (UTC)Reply
• "A density operator is a positive-semidefinite operator" -- on what?   Done XOR'easter (talk) 17:24, 23 January 2020 (UTC)Reply
• Is "quantum-mechanical observable" a synonym for "measurement"?   Done XOR'easter (talk) 17:24, 23 January 2020 (UTC)Reply
• Why does the statement of G's theorem appear twice, however in a somewhat different form?
• Further down: is the section with "Let H denote the Hilbert space..." related to the quantum-logic interpretation of the theorem?   Done The subsectioning should make this clear now XOR'easter (talk) 17:24, 23 January 2020 (UTC)Reply
• The lattice of subspaces is just the set of subspaces endowed with the containment relation, right? If so, it might be an idea to say "Each event is a subspace of H" instead of this somewhat artificial "atom of the lattice"?
• Is a "proposition" the same as speciyfing a subspace of H which has codimension 1?
• How do the x_i generate a sublattice? Just the intersections of these subspaces?
• Previously, the probability measure P was defined on H; now it seems to be defined on the set (or lattice) of all subspaces of H. How does this relate to the setup above?
• In the indented statement of G's theorem all jargon that is not crucial should be eliminated: can the mention of L be eliminated / what about the bold-face / italic x? Also the notation for the Hilbert space H should be repeated here, to make the statement as self-contained as possible.
• In many mathematical statements are of the form "all examples of an (apparently more flexible) notion arise by applying some construction to a simpler (seemingly more restrictive) notion". Is this the case here, too? I.e., I guess it is semi-obvious (??) that functions of the form <x, Wx> give a probability function on H (also in dim = 1, 2), and the content of the theorem is that the converse holds, too?   Done XOR'easter (talk) 17:24, 23 January 2020 (UTC)Reply
• It seems that the Hilbert spaces in the article are either complex or real, correct? If so, Hermitian should probably be rephrased somehow?
• The section title "Overview" is not very descriptive for the contents of the section. What about adding some subsections, and retitling it to something like "Statement (and interpretations) of the theorem"?   Done XOR'easter (talk) 17:24, 23 January 2020 (UTC)Reply

OK, I will review the remaining sections as soon as I can. Jakob.scholbach (talk) 20:22, 19 January 2020 (UTC)Reply

Thanks for your comments! They look to be very useful, and I will work to address them. The two different statements in the "Overview" section (which I agree ought to be retitled somehow) came about because when I first found the article, it had the quantum-logic version of the statement, written in a way that I found hard to follow. I tried to clean it up and also include a statement phrased in the language I was more familiar with. It's entirely possible that the repetition is more confusing than I had hoped. Anyway, thanks again, and I look forward to your feedback on the rest. XOR'easter (talk) 20:51, 19 January 2020 (UTC)Reply

OK, I've retitled, reorganized and in parts rephrased the "Overview" section. Hopefully this takes it in a good direction at least. XOR'easter (talk) 19:00, 20 January 2020 (UTC)Reply

Can you please very briefly indicate which comments of the above have been addressed? This would simplify the exchange. Jakob.scholbach (talk) 19:08, 22 January 2020 (UTC)Reply

Good idea. I will try doing so after the next round of revisions I make, since I might be able to check off a few more. XOR'easter (talk) 21:33, 22 January 2020 (UTC)Reply

History

• "in a theory founded on Hilbert space" sounds both vague and a bit ungrammatical to me.   Done Rephrased. XOR'easter (talk) 17:24, 23 January 2020 (UTC)Reply
• I am not convinced that mixing historical comments with the proof outline fits so well. You could consider putting the proof to the first section containing the statement.
• Is it possible and sensible to describe Kadison's counterexample in d=2? This could even illustrate some of the concepts earlier in the article, thus highlighting a bit further how the theorem is notable.
• I could imagine that the proof outline could be fleshed out a bit more. I (as a layman in this area) do get a reasonable overview, but I figure it makes sense to many readers of this article to get more information. For example, how does the reduction step from d>3 to d=3 work? Jakob.scholbach (talk) 19:08, 22 January 2020 (UTC)Reply

Thanks again! After so long a time when I was the only one who seemed to be taking an interest in the page, getting comments with this level of detail is really quite refreshing. I just rewrote the sentence that you rightfully pointed out as being vague. Personally, I like the mix of history and proof outline, since the particular method that Gleason used is "part of history", and other people replaced parts of his argument in the following years. But I can also see merit in dividing them up more cleanly. Regarding Kadison's counterexample, Gleason's article doesn't mention him specifically; he just makes the observation, In dimension two a frame function can be defined arbitrarily on a closed quadrant of the unit circle in the real case, and similarly in the complex case. In higher dimensions the orthonormal sets are intertwined and there is more to be said. The article by Chernoff that mentions Kadison doesn't go into detail about what his counterexample was. However, other papers give counterexamples for ${\displaystyle d=2}$ , and we could provide one of those (e.g., the one in Wright and Weigert (2018). XOR'easter (talk) 21:33, 22 January 2020 (UTC)Reply

I would suggest using the Kochen-Specker model instead (you can find it e.g. in section D.3 of arXiv:0706.2661). It is much more relevant to physics, as although it's explicitly not Born-like it can be used to reproduce the Born rule by selecting the appropriate probability distribution over the hidden variables. It was all the rage in the past few years as people were studying the limits of psi-epistemic models. Tercer (talk) 09:49, 23 January 2020 (UTC)Reply

I like that idea. I guess I had been thinking of the Kochen–Specker qubit model (and the Bell–Mermin one from section D.2) as demonstrations that hidden variables work for reproducing the quantum statistics for orthonormal measurements in dimension 2, whereas what Kadison seems to have been talking about is the possibility of statistics that don't look at all like the Born rule but are still consistent with the frame-function assumptions (because in dimension 2, there's no "intertwining"). XOR'easter (talk) 13:31, 23 January 2020 (UTC)Reply

Yeah, that's a funny conceptual twist. One can anyway do both: use equation (15) with some fixed λ as the counterexample, and remark that it can be used to build a nice hidden-variable model for a qubit, the Kochen-Specker model. Tercer (talk) 14:14, 23 January 2020 (UTC)Reply

Pseudo-review by Tercer

I'm not the actual reviewer, but I went through the article word-by-word, and I hope the resulting comments will be useful to improve it.

• In the lead, the article states that Gleason's theorem is of particular importance ... for the effort in quantum information theory to re-derive quantum mechanics from information-theoretic principles. I don't think this is true, none of the quantum information derivations I know (e.g. arXiv:quant-ph/0101012, arXiv:0911.0695, arXiv:1011.6451) use Gleason's theorem.
• The second paragraph of the lead feels a bit weird to me. Should we really try to teach quantum mechanics in the lead?
• I think the second paragraph in the subsection "Conceptual background", about pure states and mixed states, is going into too much detail about something that's not relevant for Gleason's theorem. I would remove it entirely.
• In the Quantum Logic subsection, the article states that Another way of phrasing the theorem uses the terminology of quantum logic, which makes heavy use of lattice theory. Quantum logic treats quantum events (or measurement outcomes) as logical propositions and studies the relationships and structures formed by these events, with specific emphasis on quantum measurement. This sentence here is a mess. What are quantum events? With which description of measurement outcomes? I'm not an expert in quantum logic, but as far as I know it just treats projectors (on measurement outcomes) as logical propositions. The mess becomes worse in the following paragraph: the eigenvalues ${\displaystyle \alpha _{i}}$  of an observable A are introduced, but play no role. Then a (quantum?) event is introduced as the measurement outcome ${\displaystyle x_{i}}$ . Then it is stated that events are atoms of the lattice. Now the function P is defined as summing to one when applied to "orthogonal atoms". I don't know that it means for atoms to be orthogonal. The page Atom (order theory) doesn't explain it either. Perhaps you mean orthogonal projectors? Then the probability of obtaining measurement outcome y is described as the sum of the probability of the atoms under y. But what is y? I thought the ${\displaystyle x_{i}}$  where all measurement outcomes already. Is it a union of measurement outcomes? But isn't the formula trivial in this case? Now comes the statement of Gleason's theorem, and it finally makes it clear that the ${\displaystyle x_{i}}$  are unit vectors representing logical propositions.
• In the Implications section, the article states that The mapping u → ⟨ρu,u⟩ is continuous on the unit sphere of the Hilbert space for any density operator ρ. Since this unit sphere is connected, no continuous probability measure on it can be deterministic. Is such a complicated argument really needed? I would just mention that the probability rule must be the Born rule, and that's not deterministic.
• I'm a bit worried about the first paragraph of the Generalizations section. It talks about Busch's theorem as if it is the best thing since sliced bread, but this is not really the case. The theorem didn't have much impact, because (I assume) POVMs are not fundamental, so assumptions that talk directly about them are not physically meaningful. Instead, one needs to phrase assumptions in terms of projective measurements. That's why Gleason's theorem is much more important. Now, the problem is that this is my personal opinion, and I'm not aware of a source that says the same thing, so I don't know how to include this information in the article. Tercer (talk) 15:40, 5 February 2020 (UTC)Reply

From this and the above review, it sounds like the "quantum logic" subsection is in bad shape. Looking into it, that stretch of text was apparently based closely on section 3.1 of Pitowsky (2006); as a result, it doesn't really have an encyclopedic tone. I think it could be streamlined and clarified. I'll make that the first thing on my list to fix. XOR'easter (talk) 13:33, 6 February 2020 (UTC)Reply

I've shortened and rearranged the quantum-logic material, and I added more details about how to construct a counterexample in dimension 2. XOR'easter (talk) 19:11, 15 February 2020 (UTC)Reply

That's great. I also edited the quantum logic section, I don't see any remaining issues with it. The formatting of the references is a bit bizarre, though. You have to look at the author-year, and the look for the actual reference in the list below. Is there any reason to be like this? Tercer (talk) 20:25, 15 February 2020 (UTC)Reply

The referencing was like that when I found the article, and at the time, the path of least resistance was to add to it rather than to reformat it all. (I probably didn't think that I'd be adding too many references when I started fixing the page up, and I might not have known about the {{rp}} template for providing page or section information after a footnote.) XOR'easter (talk) 20:34, 15 February 2020 (UTC)Reply

I'll help with the reformatting then. Tercer (talk) 20:45, 15 February 2020 (UTC)Reply

Thanks! Looks like we've gotten it done (and yes, it was long overdue). XOR'easter (talk) 21:32, 15 February 2020 (UTC)Reply

Well, you, I was planning to do it now but there is nothing left to do. Thanks. Tercer (talk) 07:07, 16 February 2020 (UTC)Reply

Section break

It looks like redoing the quantum-logic material has addressed several of the comments that Jakob.scholbach had. (At least, the problematic text isn't there any longer.) The remaining question that I see is how much more detail to include in the "Outline" section, like perhaps saying more about reducing the problem to ${\displaystyle \mathbb {R} ^{3}}$ . I think the current level of detail is OK, but perhaps more would be better? Opinions welcome! XOR'easter (talk) 21:51, 15 February 2020 (UTC)Reply

I'm afraid putting more detail would confuse instead of enlighten. As for the reduction of the problem to ${\displaystyle \mathbb {R} ^{3}}$ , Gleason just did the obvious thing, he showed that if a frame function in a higher dimension is regular when restricted to every three-dimensional subspace, then it is just regular. Tercer (talk) 07:06, 16 February 2020 (UTC)Reply

Where do we stand? Looking back over Jakob.scholbach's review, it seems to me that the bullet points not yet marked "done" have mostly been addressed by the trimming and refactoring of the quantum-logic material. XOR'easter (talk) 14:53, 23 February 2020 (UTC)Reply

Indeed. I had interpreted a lack of a "done" marking as the issue not being addressed, but this is not case, the unmarked issues have also been addressed. I would like to hear your thoughts about the points 2, 3, and 5 that I raised, though. Tercer (talk) 17:26, 23 February 2020 (UTC)Reply

I am sorry -- I have been incredibly slow in responding to the recent edits here, and it looks like I will not have the time needed to continue a thorough review in a reasonable time frame. Tercer, would you be willing to finish the reviewing process? You state above that you have read the article word by word, so I am very confident that you will be able to give a meaningful review without much additional effort from your side. I would be much relieved, thank you! Jakob.scholbach (talk) 20:20, 24 February 2020 (UTC)Reply

Sure, I can do it, it's pretty much finished anyway. Tercer (talk) 20:37, 24 February 2020 (UTC)Reply

Thanks, I appreciate it. Jakob.scholbach (talk) 07:51, 25 February 2020 (UTC)Reply

Final review

I decided to WP:BOLDly remove the paragraphs I found problematic, and finish the GA review.

GA review (see here for what the criteria are, and here for what they are not)

1. It is reasonably well written.

   a (prose, spelling, and grammar):   b (MoS for lead, layout, word choice, fiction, and lists):  

   I'm not really happy with the lead

2. It is factually accurate and verifiable.

   a (reference section):   b (citations to reliable sources):   c (OR):   d (copyvio and plagiarism):  

   The massive amount of work in the review was mostly dedicated to address this, now I think it is perfect.

3. It is broad in its coverage.

   a (major aspects):   b (focused):  

4. It follows the neutral point of view policy.

   Fair representation without bias:  

5. It is stable.

   No edit wars, etc.:  

6. It is illustrated by images and other media, where possible and appropriate.

   a (images are tagged and non-free content have fair use rationales):   b (appropriate use with suitable captions):  

   It's not really possible to illustrate the theorem itself with an imagine, so I think the ones it has are as good as it gets

7. Overall:

   Pass/Fail:  

   The lead should still be improved, but it's good enough for WP:GOOD.